Chapter 14

1. Chapter 14 Fluids

2. Fluids at Rest (Fluid = liquid or gas)

3. Density (r) • unit: kg/m3 • we will consider only r = m/V = constant • (incompressible fluid) • we will also assume g = constant

4. Pressure (p) • A fluid exerts a force dF normal to any area dA you consider in it. • For a fluid at rest, the force is equal and opposite on each side.

5. Pressure (p) • Why is there a force? • Microscopically: the fluid particles are in motion and collide with dA • Macroscopically: the fluid is at rest

6. Pressure (p) • pressure p is a scalar (no intrinsic direction) • reason: it acts normal to any surface dA

7. Pressure (p) • units used:pascal, millibar, atm • 1 Pa = 1 N/m2 1 millibar = 100 Pa 1 atm = 1.013×105 Pa

8. Terminology • ‘gauge pressure’ = p – patm • (can be > 0 or < 0) • (e.g., read on a car tire pressure gauge) • p = absolute pressure (> 0) = atmospheric pressure + gauge pressure = patm + gauge pressure

9. Pressure and depth • pressure: pcoordinate: y • pressure decreases with ‘elevation’ y: Derive this result and integrate it

10. Pressure and depth • coordinate: ydistance: h > 0 • p increases with depthfor any shape of vessel Demonstration: depth and shape of container

11. Exercise 14-10 • The dangers of a long snorkel tube: • Find the gauge pressure at the depth shown. Will this cause the snorkeler’s lungs to collapse? Demonstration: atmospheric pressure

12. Pascal’s Law • If any change in pressure Dp is applied at one point, it is transmitted to all points in the fluid and to walls enclosing it.

13. Example: Hydraulic Lift At equilibrium, p = F1/A1 = F2/A2 Demonstration

14. Two Pressure Gauges Notes on (b) first Notes on (a) and Exercise 14-9

15. Homework Hints: Exercise 14-55

16. Buoyancy and Buoyant Force

17. A (fully or partially) submerged object feels an upward force equal to the weight of fluid it displaces

18. (a) fluid element with weight wfluid(b) body of same shape feels buoyant force B = wfluid Demonstration

19. Surface Tension • Molecules of liquid attract each other (else no definite volume) • center: net force = 0 • surface: net force is directed inward

20. Surface Tension • So the surface acts like a membrane under tension (like a stretched drumhead) • The surface resists any change in surface area • Strength characterized by ‘surface tension’ Demonstration

21. Surface Tension g • g = F/d = cohesive force per unit length • surface tension forceF = g d • We can measure g by just balancing F Notes on measuring g Do Example 14-23

22. cohesion: attraction of like molecules example: liquid-liquid forces (surface tension)

23. adhesion: attraction between unlike moleculesexample: liquid-glass forces

24. (a) adhesion > cohesion: water wets glass(b) adhesion < cohesion: mercury beads up

25. Capillarity • For these two cases, the surface tension force F pushes the column of liquid either up or down: • (a) up for water • (b) down for mercury Notes on capillary tubes

26. Homework Announcements • Homework Set 5: Correction to hints for 14-55 (handout at front and on webpage) • Recent changes to classweb access (see HW 5 sheet at front and webpage) • Homework Sets 1, 2, 3: returned at front(scores to be entered on classweb soon)

27. Midterm Announcements • Friday: • review required topics • practice problems (from class, HW, new?) • Monday: (midterm) • you can bring a sheet of notes (both sides) • you will be given a list of equations

28. Fluid Flow (Fluid Dynamics)

29. Flow line =path of fluidelement Flow tube =bundle of flow lines passingthrough area A (just a useful construct) Flow Fluid

30. Steady flow: At any given point in the fluid, its properties (v, r, p) don’t change in time Simplifying Assumptions

31. Steady flow: different flow lines never cross each other fluid entering a flow tube never leaves it Simplifying Assumptions

32. Incompressible fluid: r = constant No friciton: no ‘viscosity’ Simplifying Assumptions

33. the same volume dV of fluid enters and exits tube: dV = volume passing through A in dt = Av dt Notes Continuity EquationA1v1 = A2v2

34. along the flow: A = area of flow tubev = speed of fluid if one increases, theother must decrease Continuity EquationA1v1 = A2v2 Notes and Demonstration: water flow

35. Where the flow lines are crowding together, the fluid speed is increasing Continuity EquationA1v1 = A2v2

36. only valid for:steady flow, incompressible fluid,no viscosity! Notes Bernoulli’s Equation

37. if v1= v2= 0: reduces to previous result for fluid at rest Bernoulli’s Equation

38. if y1= y2then for p and v: if one increases, theother must decrease Bernoulli’s Equation Demonstration

39. Applications of Bernoulli’s Equation

40. Notes Venturi Meter (Example 14-10) horizontal flow tube

41. Note: if viscosity is present, then v decreases with distance from tube center

42. Notes Venturi Meter:Homework Problem 14-90 (c) Demonstration

43. Wing Lift

44. Can’t predict flow lines but they indicate low pressure above wing, so net force up Demonstration: propellor

45. Efflux Speed: vertical flow tube Notes

46. First: you must fill the tube There is a limit:H + h < 10 m Siphon:flow tube points up, then down

47. Warm-up demonstrations Curve Ball:viscosity makes it possible

48. Viscosity drags air with spinning ball: low pressure=net force so the ball curves Demonstration

49. Homework Announcements • Homework Set 5: Correction to hints for 14-55 (handout at front and on webpage) • Recent changes to classweb access (see HW 5 sheet at front and webpage) • Homework Sets 1, 2, 3: returned at front(scores to be entered on classweb soon)